Methods for reading a memory are provided. In response to a first address signal, a first signal is obtained according to first data of the memory and a second signal is obtained according to second data of the memory by a decoding circuit. Binary representation of the first signal is complementary to that of the second signal. A first sensing signal is provided according to a reference signal and the first signal and a second sensing signal is provided according to the reference signal and the second signal by a sensing circuit. An output corresponding to the first sensing signal or the second sensing signal is output in response to a control signal, by an output buffer.

Disclosed herein is an apparatus that includes a fuse array circuit including a plurality of fuse sets each assigned to a corresponding one of a plurality of fuse addresses and configured to operatively store a fuse data, and a first circuit configured to generate and sequentially update a fuse address to sequentially read the fuse data from the plurality of fuse sets. The first circuit is configured to change a frequency of updating the fuse address based on a first signal.

In an example, a multiplexer is provided. The multiplexer may include one or more first strings controlling access to source-lines of the memory, wherein a first string of the one or more first strings includes a first set of two high voltage transistors and a first plurality of low voltage transistors. The multiplexer may include one or more second strings controlling access to bit-lines of the memory, wherein a second string of the one or more second strings includes a second set of two high voltage transistors and a second plurality of low voltage transistors. A method for operating such multiplexer is provided.

Various implementations described herein are directed to a device having memory architecture with an array of memory cells arranged in multiple columns with redundancy including first columns of memory cells disposed in a first region along with second columns of memory cells and redundancy columns of memory cells disposed in a second region that is laterally opposite the first region. The device may have column shifting logic that is configured to receive data from the multiple columns, shift the data from the first columns in the first region to a first set of the redundancy columns in the second region, and shift data from the second columns in the second region to a second set of the redundancy columns in the second region.

A memory device includes an external information input circuit configured to generate a burst mode signal and a write command pulse for a write operation, by receiving external information for the write operation; and a write operation control circuit configured to generate a write control pulse for storing internal data in a cell array, from the write command pulse when a first burst mode is performed on the basis of the burst mode signal, and to control whether to generate the write control pulse from the write command pulse when a second burst mode is performed on the basis of the burst mode signal.

The invention relates to a method for operating a memory assembly. A physical address is received. The physical address is associated with a first memory segment of a memory assembly. The physical address is modified to a modified physical address. The modified physical address is associated with a second memory segment of the memory assembly.

A memory device includes a command interface configured to receive a two-cycle command from a host device via multiple command address bits. The memory device also includes a command decoder configured to decode a first portion of the multiple command address bits in a first cycle of the two-cycle command. The command decoder includes mask circuitry. The mask circuitry includes mask generation circuitry configured to generate a mask signal. The mask circuitry also includes multiplexer circuitry configured to apply the mask signal to block the command decoder from decoding a second portion of the multiple command address bits in a second cycle of the two-cycle command.

An apparatus is described. The apparatus includes logic circuitry to multiplex on a data bus a first data burst, a second data burst, a third data burst and a fourth data burst having different respective base target addresses that respectively target a first memory rank, a second memory rank, a third memory rank and a fourth memory rank. A first data transfer for the first data burst occurs on a first edge of a first pulse of a data strobe signal for the data bus and a second data transfer for the second data burst occurs on a second edge of the first pulse of the data strobe signal. A third data transfer for the third data burst occurs on a first edge of a second pulse of the data strobe signal for the data bus and a fourth data transfer for the fourth data burst occurs on a second edge of the second pulse. The second pulse immediately follows the first pulse on the data strobe signal. The first memory rank, the second memory rank, the third memory rank and the fourth memory rank are on a same memory module.

The present disclosure includes apparatuses and methods related to memory alignment. An example method comprises performing an alignment operation on a first byte-based memory element and a second byte-based memory element such that a padding bit of the first byte-based memory element is logically adjacent to a padding bit of the second byte-based memory element and a data bit of the first byte-based memory element is logically adjacent to a data bit of the second byte-based memory element.

Methods, systems, and devices related to domain-based access in a memory device are described. In one example, a memory device in accordance with the described techniques may include a memory array, a sense amplifier array, and a signal development cache configured to store signals (e.g., cache signals, signal states) associated with logic states (e.g., memory states) that may be stored at the memory array (e.g., according to various read or write operations). The memory array may be organized according to domains, which may refer to various configurations or collections of access lines, and selections thereof, of different portions of the memory array. In various examples, a memory device may determine a plurality of domains for a received access command, or an order for accessing a plurality of domains for a received access command, or combinations thereof, based on an availability of the signal development cache.